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	Volume 5, Issue 2 Pg 107 - 218 (April 2009)
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Advances and Applications in Fluid Mechanics

Advances and Applications in Fluid Mechanics
Volume 5, Issue 1, Pages 1 - 25 (January 2009)

RECENT CFD ACTIVITIES AT ONERA: IMPLICIT STAGES FOR COMPLEX FLOW SIMULATIONS AND GRADIENT COMPUTATION FOR SHAPE OPTIMIZATION Jacques Peter (France), Chi-Tuan Pham (France) and Frederique Drullion (USA) Received July 16, 2008 References:
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Muller, Adjoint code developments using the exact discrete approach, AIAA Paper 2001-2596, 2001. [8] A. Harten and H. Hyman, Self adjusting grid methods for one-dimensional hyperbolic conservation laws, J. Comput. Phys. 50 (1983), 235-269. [9] C. Hirsch, Numerical Computation of Internal and External Flows, John Wiley and Sons, Vol. 1, 1989, Vol. 2, 1990. [10] A. Jameson, Multigrid algorithms for compressible flow calculations, Lecture Notes in Mathematics, 1228, Springer Verlag, 1985. [11] A. Jameson, Aerodynamic Design via Control Theory, ICASE Report and Course VKI, 1988. [12] A. Jameson, N. A. Pierce and L. Martinelli, Optimum aerodynamic design using the Navier-Stokes equations, AIAA Paper 97-0101, 1997. Theoretical and Computational Fluid Dynamics 10(1) (1998), 213-237. [13] A. Jameson, W. Schmidt and E. Turkel, Numerical solutions of the Euler equations by finite volume methods using Runge-Kutta time stepping schemes, AIAA Paper 81-1259, 1981. [14] H. J. Kim, C. A. Kim, O. H. Rho and K. D. Lee, Aerodynamic sensitivity analysis for Navier-Stokes equations, AIAA Paper 99-0402, 1999. [15] C. S. Kim, C. Kim and O. H. Rho, Sensitivity analysis for the Navier-Stokes equations with two-equation turbulence models, AIAA J. 39(5) (2001), 838-845. [16] C. S. Kim, C. Kim and O. H. Rho, Effects of constant eddy viscosity assumption on gradient-based design optimization, AIAA Paper 2002-0262, 2002. [17] G. Kuruvila, R. P. Narducci and S. Agrawal, Development and application of TLNS3D-adjoint: A practical tool for aerodynamic shape optimization, AIAA Paper 2001-2400, 2001. [18] A. LeMoigne and N. Qin, A discrete adjoint method for aerodynamic sensitivities for Navier-Stokes flows, CEAS Aerodynamics Research Conference, Cambridge, June 2002. [19] L. Martinelli, Calculation of viscous flows with a multigrid method, Ph.D. Diss. Princeton University, 1987. [20] M. Meaux, M. Cormery and G. Voizard, Viscous aerodynamic shape optimization based on the discrete adjoint state for 3D industrial configurations, Proceedings of ECCOMAS 04, Jyvaskyla, July 2004. [21] M. Michel, C. Quemart and R. Durant, Application d un schï¿½ma de longueur de mï¿½lange ï¿½ l ï¿½tï¿½de des couches limites turbulentes d ï¿½quilibre, Technical Note 154, Office National d Etudes et Recherches Aï¿½rospatiales, 1969. [22] N. Nemec and D. W. Zingg, Towards efficient aerodynamic shape optimization based on the Navier-Stokes equations, AIAA Paper 2001-2532, 2001. [23] E. J. Nielsen and W. K. Anderson, Aerodynamic design optimization on structured meshes using the Navier-Stokes equations, AIAA Paper 98-4809, 1998, [24] E. J. Nielsen and W. K. Anderson, Aerodynamic design optimization on unstructured meshes using the Navier-Stokes equations, AIAA J. 37 (11) (1999), 185-191. [25] E. J. Nielsen and W. K. Anderson, Recent improvements in aerodynamic design optimization on unstructured meshes, AIAA J. 40(6) (2002), 1155-1163. [26] J. Peter, Etude de schï¿½mas numï¿½riques pour la rï¿½solution des ï¿½quations de Navier-Stokes instationnaires, Application ï¿½ des ï¿½coulements en turbomachines, Thï¿½se ENSAM and Publication ONERA (1996), 1999-4. [27] J. Peter and F. Drullion, Large stencil viscous flux linearization for the simulation of 3D compressible turbulent flows with Backward-Euler schemes, Computers and Fluids 36 (2007), 1007-1027. [28] J. Peter, F. Drullion and C. T. Pham, Contribution to discrete implicit gradient and discrete adjoint method for aerodynamic shape optimization, Proceedings of ECCOMAS 04, Jyvaskyla, July 2004. [29] P. L. Roe, Approximate Riemann solvers, parameters vectors, and difference schemes, J. Comput. Phys. 43 (1981), 292-306. [30] R. Selvaggini, Essais de la demi-maquette AS28 dans la veine N1-42, 6m2, de la soufflerie S1MA, Partie effect Reynolds, October-November 1984. PV no. 2/09662 GY, fascicule 2/4, June 1985. [31] G. R. Shubin, Obtaining Cheap Optimization Gradients from Computational Aerodynamics Codes, Boeing Computer Service, Applied Mathematics and Statistics Technical Report, AMSTR-164, June 1991. [32] G. R. Shubin and P. D. Frank, A Comparison of the Implicit Gradient Approach and the Variationnal Approach to Aerodynamic Design Optimization, Boeing Computer Service, Applied Mathematics and Statistics Technical Report, AMS-TR-163, June 1991. [33] B. I. Soemarwoto, The Variational Method for Aerodynamic Optimization using the Navier-Stokes Equations, NASA C-R97-206277, ICASE Report No. 97-71, December 1997. [34] J. Swanson and E. Turkel, On central-difference and upwind schemes, J. Comput. Phys. 101 (1992), 292-306. [35] V. 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Keywords and phrases: backward-Euler scheme, implicit stage, discrete sensitivity analysis, algebraic turbulence model.

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